Exploring photoexcited spin states for fullerene-derivatives based organic bulk heterojunction solar cells using magneto-photocurrent

Hu, Jiaji; Kan, Lixuan; Xie, Yongchao; Zhu, Xixiang; Yu, Haomiao; Li, Jinpeng; Zhang, Fujun; Duan, Wubiao; Wang, Kai

doi:10.1063/5.0187765

Applied Physics Letters

2024

DOI: 10.1063/5.0187765

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Exploring photoexcited spin states for fullerene-derivatives based organic bulk heterojunction solar cells using magneto-photocurrent

Jiaji Hu,

Lixuan Kan,

Yongchao Xie

et al.

Abstract: Fullerene-derivatives based bulk heterojunctions hold an exceptionally important role on the roadmap of highly efficient organic solar cells (OSCs). In recent years, the utilization of the non-fused ring acceptors based OSCs has further improved photovoltaic power conversion efficiencies. Among these, one of the fundamental issues is to explore and to understand the spin-related polaron dissociation at charge transfer states because they act as the central unit for the photovoltaic action. It is also eagerly i… Show more

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Spin effect in the ferromagnetic organic photovoltaics cells

Tong,

Xie,

Chen

et al. 2025

Organic Electronics

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Spin effect in the ferromagnetic organic photovoltaics cells

Tong,

Xie,

Chen

et al. 2025

Organic Electronics

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Unlocking amplified magneto-photocurrent using multi-field manipulation in nonfullerene organic bulk heterojunction systems

Hu,

Kan,

Xie

et al. 2024

The Journal of Chemical Physics

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An effective manipulation of polaron pairs (PPs) for realizing amplified magneto-photocurrent (AMPC) is of critical importance toward the development of low power consumption and high-performance organic spin-optoelectronic devices, for instance magneto-photo-volatile memories. By far, it is challenging and there is a lack of method to reach AMPC. The typical magneto-photocurrent due to the light–matter interanion is primarily for unveiling the spin-dependent electron–hole dissociation in organic solar cells. Herein, we achieved an AMPC of ∼140% in nonfullerene organic bulk heterojunction systems at room temperature. We found that the amplification can be effectively triggered by a multi-field to a large number of photogenerated PPs at intermediate charge transfer states. We further postulate that, at steady state, they may experience a cyclic photophysical process due to the triplet-exciton polaron interaction. This study paves the way for the realization of AMPC in the organic spin-optoelectronic system.

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Exploring photoexcited spin states for fullerene-derivatives based organic bulk heterojunction solar cells using magneto-photocurrent

Cited by 2 publications

References 50 publications

Spin effect in the ferromagnetic organic photovoltaics cells

Spin effect in the ferromagnetic organic photovoltaics cells

Unlocking amplified magneto-photocurrent using multi-field manipulation in nonfullerene organic bulk heterojunction systems

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